US9950101B2ExpiredUtilityPatentIndex 96
Blood pump
Est. expiryJun 6, 2025(expired)· nominal 20-yr term from priority
Inventors:SMITH WILLIAMLORENZ MARKUSDUDZINSKI DAVIDCHEN HSIANG-MINGCHAPMAN JR PETER APRISCO CHARLES JVITALE NICHOLAS GWEBER STEPHAN
A61M 1/125A61M 1/1015A61M 1/12A61M 1/1008A61M 1/1031A61M 1/1012A61M 1/101A61M 1/122A61M 1/127A61M 60/135A61M 60/865A61M 60/82A61M 60/876A61M 60/562A61M 60/216A61M 60/183A61M 60/422A61M 60/148
96
PatentIndex Score
40
Cited by
95
References
65
Claims
Abstract
A blood pump ( 20 ) includes a stator assembly comprising a motor stator ( 52 ), a fluid inlet ( 24 ), and a fluid outlet ( 26 ). A rotor assembly includes a motor rotor ( 54 ) and an impeller ( 40 ) rotatable about an axis ( 44 ) to move fluid from the inlet ( 24 ) to the outlet ( 26 ). An outflow sheath ( 300 ) directs the flow along the outside of the pump ( 20 ).
Claims
exact text as granted — not AI-modifiedHaving described the invention, the following is claimed:
1. A blood pump comprising:
a stator assembly comprising a motor stator, a fluid inlet, and a fluid outlet;
a rotor assembly comprising a motor rotor and an impeller rotatable about an axis to move fluid from the inlet to the outlet; and
an outflow sheath for directing the fluid that has been discharged from the outlet to flow along the outside of the pump.
2. The blood pump recited in claim 1 , wherein the outflow sheath has a flexible construction that allows the sheath to be collapsed and wrapped around an outer surface of the pump for implantation.
3. The blood pump recited in claim 2 , wherein the flow produced during operation of the pump expands the sheath to allow the flow to pass through a radial space defined between the pump and the sheath.
4. The blood pump recited in claim 1 , further comprising a power cable for supplying electrical power to the blood pump, the power cable comprising an anchoring point for the sheath.
5. The blood pump recited in claim 1 , further comprising reinforcing bands that help limit expansion of the sheath.
6. The blood pump recited in claim 1 , wherein the sheath is secured to the stator assembly at a location positioned between the fluid inlet and the fluid outlet.
7. The blood pump recited in claim 1 , wherein the sheath is constructed such that the fluid inlet and fluid outlet can be placed in a first location with the sheath extending along the outside of the pump and through a lumen into a second location, the sheath forming a conduit for directing pumped blood from the fluid outlet positioned in the first location through the lumen and into the second location.
8. The blood pump recited in claim 1 , wherein the sheath is constructed such that the fluid inlet and fluid outlet can be placed in a left ventricle of the heart with the sheath extending along the outside of the pump and through a heart valve into the aorta, the sheath forming a conduit for directing pumped blood from the fluid outlet positioned in the left ventricle through the heart valve and into the aorta.
9. The blood pump recited in claim 1 , wherein the sheath is constructed such that the fluid inlet and fluid outlet can be placed in a right ventricle of the heart with the sheath extending along the outside of the pump and through a heart valve into the pulmonary trunk, the sheath forming a conduit for directing pumped blood from the fluid outlet positioned in the right ventricle through the heart valve and into the pulmonary trunk.
10. The blood pump recited in claim 9 , wherein the radial bearing stator comprises at least one permanent magnet that extends less than 360 degrees about the stator assembly.
11. The blood pump recited in claim 1 , further comprising an attached catheter to facilitate insertion in a patient's heart from a remote location in the patient's circulatory tree.
12. The blood pump recited in claim 1 , wherein a radial motor gap is defined between the between the motor stator and the motor rotor, the pump being configured to direct a primary flow from the fluid inlet to the fluid outlet over an outside diameter of the motor assembly and being configured to direct a wash flow through the motor gap.
13. The blood pump recited in claim 12 , wherein the primary flow is discharged through the outlet at an intermediate angle having both axial and radial components so that the primary flow is directed along an outside surface of the stator assembly that extends the length of the motor stator.
14. The blood pump recited in claim 12 , wherein the sheath maintains the primary flow along the outside diameter of the motor assembly.
15. The blood pump recited in claim 12 , wherein the motor gap is defined at least partially by a surface having a non-circular cross-section.
16. The blood pump recited in claim 1 , wherein the sheath extends axially beyond the length of the stator assembly.
17. The blood pump recited in claim 1 , further comprising a permanent magnet radial bearing for supporting the rotor assembly for rotation about the axis, the radial bearing comprising:
a permanent magnet radial bearing stator fixed to the stator assembly and a permanent magnet radial bearing rotor fixed to the rotor assembly, the radial bearing being configured such that the radial bearing stator magnets and the radial bearing rotor magnets are axially offset from each other when the pump is at rest.
18. The blood pump recited in claim 17 , wherein the offset of the radial bearing stator magnets and the radial bearing rotor magnets is configured to balance with hydrodynamic forces created by pumping action of the impeller.
19. The blood pump recited in claim 17 , further comprising front and rear stop points configured to limit an axial range of motion of the rotor assembly relative to the stator assembly in order to maintain the axial offset of the radial bearing stator magnets and the radial bearing rotor magnets.
20. The blood pump recited in claim 19 , wherein at least one of the front and rear stop points comprises a magnetic axial bearing.
21. The blood pump recited in claim 19 , wherein the stop points comprise surface profiles configured to generate hydrodynamic lifting forces.
22. The blood pump recited in claim 19 , wherein the stop points are configured to prevent the radial bearing magnets from statically crossing over an unstable magnetic equilibrium point.
23. The blood pump recited in claim 19 , wherein at least one of the front and rear axial stop points comprise a bearing surface that is formed with a synthetic jewel material, and a bearing surface that is formed with a ceramic material.
24. The blood pump recited in claim 19 , wherein at least one of the front and rear stop points comprises a flat bearing surface on the stator and a curved bearing surface on the rotor.
25. The blood pump recited in claim 17 , wherein:
the radial bearing stator comprises a plurality of ring shaped stator magnets arranged next to each other in opposing polarity; and
the radial bearing rotor comprises a plurality of ring shaped rotor magnets arranged next to each other in opposing polarity;
the pump being configured such that, during operation, the stator magnets and rotor magnets are positioned with like polarities opposing each other.
26. The blood pump of claim 25 , wherein the ring shaped rotor and stator magnets include a combination of axially and radially polarized elements.
27. The blood pump recited in claim 1 , wherein the motor stator comprises an ironless motor stator.
28. The blood pump recited in claim 1 , wherein the rotor has a 2-pole magnetic geometry.
29. The blood pump recited in claim 1 , the motor stator further comprising a thin outer shell of magnetic material.
30. The blood pump recited in claim 1 , further comprising an inflow stator having vanes with a curvature reversed from the curvature of vanes on the impeller.
31. The blood pump recited in claim 1 , further comprising means for measuring a pump internal temperature as a pump control input.
32. The blood pump recited in claim 31 , wherein the means for measuring the pump internal temperature comprises a motor winding resistance measurement.
33. The blood pump recited in claim 1 , wherein the motor stator comprises motor windings that are formed in a racetrack shape.
34. The blood pump recited in claim 1 , wherein the impeller comprises an impeller blade having a leading edge with an angle that varies from a hub of the impeller to a tip of the impeller blade.
35. The blood pump recited in claim 1 , wherein the stator assembly further comprises at least one of an impeller inlet stator blade and an impeller outlet stator blade.
36. The blood pump recited in claim 35 , wherein at least one of the impeller inlet stator blade and the impeller outlet stator blade has a variable thickness from a leading edge to a trailing edge.
37. The blood pump recited in claim 1 , further comprising an inflow cannula that is axially deformable, radially non-collapsible, and impermeable.
38. The blood pump recited in claim 1 , further comprising a biocompatible power cable configured to help support and advance the blood pump along a blood vessel.
39. The blood pump recited in claim 38 , further comprising at least one channel in the power cable for receiving a guide wire.
40. The blood pump recited in claim 39 , further comprising at least one guide wire insertable in the at least one channel.
41. The blood pump recited in claim 40 , wherein the guide wire is deformable and configured so as to be capable of holding a deformed shape.
42. The blood pump recited in claim 39 , wherein the channel is configured to facilitate advancing the guide wire ahead of the pump during placement.
43. The blood pump recited in claim 39 , wherein the channel is configured to be self sealing when the wire is retracted into the cable.
44. The blood pump recited in claim 1 , wherein the sheath is positioned outside the pump so that fluid discharged from the outlet engages the sheath, which directs the fluid to flow along the outside of the pump.
45. The blood pump recited in claim 1 , wherein the sheath is positioned outside the pump so as to define an annular space between the stator assembly and the sheath, the fluid discharged from the outlet entering the annular space and being directed to flow along the outside of the pump.
46. A blood pump comprising:
a housing comprising an elongated tubular side wall that extends along a central axis of the blood pump, the housing having a fluid inlet and a fluid outlet, the fluid outlet comprising at least one opening in the side wall;
an impeller positioned in the housing for rotation about the axis, at least a portion of the impeller being positioned between the fluid inlet and the fluid outlet;
a motor for imparting rotation of the impeller about the axis to draw fluid into the pump through the inlet and discharge the fluid from the pump through the outlet, the motor comprising a stator fixed to the housing and a rotor coupled to the impeller; and
an outflow sheath for directing the fluid that has been discharged from the outlet to flow along an outside surface of the housing.
47. The blood pump recited in claim 46 , wherein the outflow sheath has a flexible construction that allows the sheath to be collapsed and wrapped around an outer surface of the pump for implantation.
48. The blood pump recited in claim 47 , wherein the flow produced during operation of the pump expands the sheath to allow the flow to pass through a radial space defined between the pump and the sheath.
49. The blood pump recited in claim 46 , further comprising a power cable for supplying electrical power to the blood pump, the power cable comprising an anchoring point for the sheath.
50. The blood pump recited in claim 46 , further comprising reinforcing bands that help limit expansion of the sheath.
51. The blood pump recited in claim 46 , wherein a radial motor gap is defined between the between the motor stator and the motor rotor, the pump being configured to direct a primary flow from the fluid inlet to the fluid outlet over an outside diameter of the motor assembly and being configured to direct a wash flow through the motor gap.
52. The blood pump recited in claim 51 , wherein the sheath maintains the primary flow along the outside diameter of the motor assembly.
53. The blood pump recited in claim 46 , wherein the sheath extends axially beyond the length of the housing.
54. The blood pump recited in claim 46 , further comprising a permanent magnet radial bearing for supporting the rotor assembly for rotation about the axis, the radial bearing comprising a permanent magnet radial bearing stator fixed to the stator assembly and a permanent magnet radial bearing rotor fixed to the rotor assembly, the radial bearing being configured such that the radial bearing stator magnets and the radial bearing rotor magnets are axially offset from each other when the pump is at rest.
55. The blood pump recited in claim 54 , wherein the offset of the radial bearing stator magnets and the radial bearing rotor magnets is configured to balance with hydrodynamic forces created by pumping action of the impeller.
56. The blood pump recited in claim 54 , further comprising front and rear stop points configured to limit an axial range of motion of the rotor assembly relative to the stator assembly in order to maintain the axial offset of the radial bearing stator magnets and the radial bearing rotor magnets.
57. The blood pump recited in claim 56 , wherein the stop points are configured to prevent the radial bearing magnets from statically crossing over an unstable magnetic equilibrium point.
58. The blood pump recited in claim 46 , wherein the sheath is secured to the stator assembly at a location positioned between the fluid inlet and the fluid outlet.
59. The blood pump recited in claim 46 , wherein the sheath is constructed such that the fluid inlet and fluid outlet can be placed in a first location with the sheath extending along the outside of the pump and through a lumen into a second location, the sheath forming a conduit for directing pumped blood from the fluid outlet positioned in the first location through the lumen and into the second location.
60. The blood pump recited in claim 46 , wherein the sheath is constructed such that the fluid inlet and fluid outlet can be placed in a left ventricle of the heart with the sheath extending along the outside of the pump and through a heart valve into the aorta, the sheath forming a conduit for directing pumped blood from the fluid outlet positioned in the left ventricle through the heart valve and into the aorta.
61. The blood pump recited in claim 46 , wherein the sheath is constructed such that the fluid inlet and fluid outlet can be placed in a right ventricle of the heart with the sheath extending along the outside of the pump and through a heart valve into the pulmonary trunk, the sheath forming a conduit for directing pumped blood from the fluid outlet positioned in the right ventricle through the heart valve and into the pulmonary trunk.
62. The blood pump recited in claim 46 , wherein the sheath is positioned outside the pump so that fluid discharged from the outlet engages the sheath, which directs the fluid to flow along the outside surface of the housing.
63. The blood pump recited in claim 46 , wherein the sheath is positioned outside the pump so as to define an annular space between the housing and the sheath, the fluid discharged from the outlet entering the annular space and being directed to flow along the outside surface of the housing.
64. A blood pump comprising:
a stator assembly comprising a motor stator, a fluid inlet, and a fluid outlet;
a rotor assembly comprising a motor rotor and an impeller rotatable about an axis to move fluid from the inlet to the outlet; and
an outflow sheath for directing the flow along the outside of the pump, wherein the sheath is effective to extend the fluid outlet axially downstream of the fluid inlet.
65. A blood pump comprising:
a housing comprising an elongated tubular side wall that extends along a central axis of the blood pump, the housing having a fluid inlet and a fluid outlet, the fluid outlet comprising at least one opening in the side wall;
an impeller positioned in the housing for rotation about the axis, at least a portion of the impeller being positioned between the fluid inlet and the fluid outlet;
a motor for imparting rotation of the impeller about the axis, the motor comprising a stator fixed to the housing and a rotor coupled to the impeller; and
an outflow sheath for directing the flow along an outside surface of the housing, wherein the sheath is effective to extend the fluid outlet axially downstream of the fluid inlet.Cited by (0)
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References (0)
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